1 / 23

Uncontrolled copy not subject to amendment

Uncontrolled copy not subject to amendment. Rocketry. Revision 1.00. Chapter 5 Rocket Structures and Systems. Forces on a Rocket. When a rocket lifts off there are three main forces acting on it. Thrust from the motor, at the bottom of the rocket trying to push it upwards.

bill
Télécharger la présentation

Uncontrolled copy not subject to amendment

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Uncontrolled copy not subject to amendment Rocketry Revision 1.00

  2. Chapter 5Rocket Structures and Systems

  3. Forces on a Rocket • When a rocket lifts off there are three main forces acting on it. • Thrust from the motor, at the bottom of the rocket trying to push it upwards. • The weight of the rocket, propellant and payload, trying to hold the rocket on the ground. • Aerodynamic drag, pushing on the nose and trying to slow the rocket down.

  4. Forces on a Rocket • Thrust • Depends on the amount of propellant and oxidiser that is being burned in the combustion chamber. • Weight • The weight of the empty rocket is called its dry mass • The total weight is the dry mass plus the weight of the payload and fuels. • Drag • Depends on the aerodynamic shape of the rocket and its velocity • As velocity increase the amount of drag increases.

  5. Forces on a Rocket • At lift off the rocket is stationary • Thrust must be greater than the weight to lift the rocket • Thrust to weight ratio is about 1.2 to 1.6 for a launch vehicle • Drag is zero because the rocket isn’t moving • Once the rocket is moving • Thrust must be greater than drag plus weight • Weight decreases as propellant is burned • Drag increases as the rocket gains speed. • The thrust and drag try to “crush” the rocket • At “max Q” these forces are at their greatest

  6. Rocket Performance • Rockets must be light and strong to perform well • Two standard ratios that are used to asess the strength and weight of a rocket • mass ratio. This is defined as the ratio of the rocket with propellant (the wet mass) to the ratio of the rocket without propellant (the dry mass) • propellant mass fraction. This is defined as the ratio of the mass of propellant to the wet mass of the rocket. The propellant mass fraction shows how much of the lift-off mass is propellant.

  7. Rocket Performance If m0 is the initial total mass, including propellant, mf is the final total mass, and mp is the mass of propellant, then: mf Mass ratio = m0 mp Propellant mass fraction = m0 A propellant mass fraction above 0.8 is regarded as good, and some modern rockets have propellant mass fractions of over 0.85. The propellant mass fraction of the Space Shuttle is about 0.82.

  8. Rocket Performance • The table shows the mass ratio of some rockets. The newest (Ariane 5) is at the top, and the oldest (V2) is at the bottom. • The continuing improvement in rocket design is very clear from this table.

  9. Rocket Structures • Rockets need to be as light as possible to increase the thrust to weight ratio • Rockets need to retain their strength and stiffness throughout launch and flight • How do you make a rocket light and strong? • use lightweight materials • thicken the outer skin • add struts and other structural parts • BUT every kg of metal that is added to the rocket a kg of payload or fuel has to be removed • This reduces the usefulness of the rocket

  10. Rocket Structures • The rocket structure • Transmits the thrust through the rocket to the payload • Supports internal components, for example fuel tanks and electronics • Structures need to be light • The motor lifts as little surplus weight as possible • Allows the rocket to carry the maximum payload and fuel • Structures need to be strong • The rocket must not bend or crumple in flight

  11. Rocket Structures • One common structure attaches all components to a tubular frame • The frame comprises • struts which run the length of the rocket body • ribs which run around the body • Motor, tanks and guidance systems are attached to the frame using support structures • A lightweight skin is attached to the frame • panels allow access for maintenance and testing

  12. Rocket Structures

  13. Rocket Structures • An alternative structure uses no frame, just a skin • Called a monocoque structure • The rocket is pressurised to make the skin stretch and stiffen the rocket • The propellant tanks use the skin of the rocket as their outer wall • Helium is pumped into the tank to maintain pressure as fuel and oxidiser are consumed. • This also provides a blowdown system for propellant •  This structure is relatively light

  14. Rocket Structures

  15. Guidance • Like aircraft, rockets can spin or roll, the nose can pitch up and down, and the rocket can yaw from side to side. • Aeronautical engineers define roll, pitch and yaw as rotations around imaginary lines (called axes) which pass through the centre of gravity of a rocket.

  16. Guidance • In a rocket the roll axis is about the direction of travel, just like an aircraft. • It is difficult to define pitch and yaw axes in a round bodied rocket or missile. • Rocket and missile engineers choose these directions arbitrarily, usually aligning the axes with the direction of fins or the orientation of any gyroscopes inside the rocket.

  17. Guidance • The control surfaces of an aircraft interact with the air to generate forces, and these forces are used to turn the aircraft. • Missiles usually operate inside the atmosphere so they often use control surfaces to “fly” in a similar manner to an aircraft. • These control surfaces, called fins, are used to aligned with the yaw and pitch axes, and are deflected to produce aerodynamic forces.

  18. Guidance • The AIM-9 Sidewinder used two sets of fins to steer the missile. • The forward fins controlled pitch and yaw, and worked in pairs to steer the missile. • The aft fins controlled roll using an ingenious gyroscope system powered by the airflow over the fins.

  19. Guidance • Many of Robert Goddard’s more successful rockets guided the rocket by inserting vanes into the exhaust plume. • Inserting a vane deflected the flow changed the direction of the thrust. • A set of four vanes allowed the rocket to be steered in both pitch and yaw. Rigid fins controlled the roll of the rocket. • This system was later used by Wernher von Braun in the V2

  20. Guidance • This picture shows the vanes on the back of a Robert Goddard rocket from 1935. • Goddard made his vanes from metal. Because his rockets were experimental the engine only burned for a few seconds. • The metal vanes did not have time to melt in the hot exhaust plume during such short flights.

  21. Guidance • Engineers realised that it was easy to mount the engine on gimbals and tilt the whole motor using hydraulics. • Tilting the motor changed the direction of the thrust, which caused the rocket to pitch or yaw. • This technique is still commonly used in modern rockets and missiles.

  22. Guidance • This picture shows the Vulcain engine, made by EADS and used on the Ariane 5 launch vehicle. • The gimbal can be seen at the top the combustion chamber.

  23. Guidance • Another technique, used on larger rockets and in space, is to have small thrusters on the rocket. • These are mounted to give a sideways thrust. • When it is necessary to steer the rocket one or more of these thrusters is fired, nudging the rocket in pitch or yaw.

More Related